Pump assembly

ABSTRACT

The present embodiments relate to a pump assembly comprising a pump which in turn comprises a low side and a high side. The pump assembly comprises a first inlet conduit in fluid communication with the low side and the pump assembly is adapted to provide a first operation condition in which first operation condition fluid is transported in the first inlet conduit towards the low side at a first flow rate. The pump assembly is further adapted to provide a second operation condition in which second operation condition fluid is transported in the first inlet conduit towards the low side at a second flow rate, wherein the first flow rate is lower than the second flow rate.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to Provisional Patent Application No. 61/109,271 which was filed on Oct. 29, 2008 and Swedish Patent Application No. 0802287-3 which was filed on Oct. 27, 2008, the entirety of which is incorporated by reference herein.

BACKGROUND

1. Field

The present invention relates to a pump assembly comprising a pump which in turn comprises a low side and a high side. The pump assembly comprises a first inlet conduit in fluid communication with the low side and the pump assembly is adapted to provide a first operation condition in which first operation condition fluid is transported in the first inlet conduit towards the low side at a first flow rate. The pump assembly is further adapted to provide a second operation condition in which second operation condition fluid is transported in the first inlet conduit towards the low side at a second flow rate, wherein the first flow rate is lower than the second flow rate.

2. Description of the Related Art

A pump assembly generally comprises an inlet conduit assembly, a pump and an outlet conduit assembly. The inlet conduit assembly is often connected to a low side of the pump whereas the outlet conduit assembly often is connected to a high side of the pump such that the pump assembly—in a fluid transport condition—is capable of transporting a fluid—such as a liquid—from the inlet conduit assembly to the outlet conduit assembly.

Generally, the pump of the pump assembly has a preferred operating condition at a specific combination of the flow rate and pressure or at preferred ranges of the flow rate and/or pressure of the fluid entering the low side of the pump.

If the flow rate changes during a pumping operation—e.g. for instance during the aforesaid fluid transport condition—there is a risk that the flow rate of the fluid entering the low side of the pump will fall outside the preferred flow rate range. For instance, the flow rate of the fluid entering the low side of the pump may fall below the lowest preferred flow rate for the pump.

The latter scenario may arise when for example a vessel, connected to the inlet conduit assembly of the pump assembly, is emptied of liquid. When the vessel is almost completely emptied of liquid, the liquid flow from the vessel to the pump is generally lower than in the beginning of the vessel emptying operation which may result in a flow rate under the lowest preferred flow rate for the pump. The low flow rate may in turn result in that the pump does not function properly and/or that the pump may be subjected to wear and tear.

In view, of the above, a need exists for improvements in the field of pump assemblies.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features of the present invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.

FIG. 1 depicts a schematic side view of a pump assembly of the present invention;

FIG. 2 depicts a schematic side view of an embodiment of the pump assembly of the present invention;

FIG. 3A depicts a schematic side view of a further embodiment of the pump assembly of the present invention when the pump assembly is in a second operating condition;

FIG. 3B depicts a schematic side view of the FIG. 3A embodiment of the pump assembly of the present invention when the pump assembly is in a first operating condition;

FIG. 3C depicts an enlargement of a portion of the FIG. 3B embodiment of the pump assembly of the present invention;

FIG. 4 depicts a schematic side view of an additional embodiment of the pump assembly of the present invention, and

FIG. 5 depicts a flow chart illustrating steps of a preferred method of the third aspect of the present invention.

DETAILED DESCRIPTION

A detailed description will now be provided. Each of the appended claims defines a separate invention, which for infringement purposes is recognized as including equivalents to the various elements or limitations specified in the claims. Depending on the context, all references below to the “invention” may in some cases refer to certain specific embodiments only. In other cases it will be recognized that references to the “invention” will refer to subject matter recited in one or more, but not necessarily all, of the claims. Each of the inventions will now be described in greater detail below, including specific embodiments, versions and examples, but the inventions are not limited to these embodiments, versions or examples, which are included to enable a person having ordinary skill in the art to make and use the inventions, when the information in this patent is combined with available information and technology.

A first object of the invention is to overcome or ameliorate at least one of the disadvantages of the prior art, or to provide a feasible alternative.

A second object of the present invention is to provide a pump assembly, wherein adverse effects on the pump due to air mixed in the liquid pumped by the pump is reduced.

A third object of the present invention is to provide a pump assembly, which provides for that the pump of the pump assembly may operate at flows and pressures which are close to the flow and the pressure of the optimum operating condition of the pump even when the flow and/or pressure of the liquid fed to the pump may vary.

At least one of the objects above may be achieved by a pump assembly according to claim 1.

As such, the present invention relates to a pump assembly comprising a pump which in turn comprises a low side and a high side. The pump assembly comprises a first inlet conduit in fluid communication with the low side and the pump assembly is adapted to provide a first operation condition in which first operation condition fluid is transported in the first inlet conduit towards the low side at a first flow rate. The pump assembly is further adapted to provide a second operation condition in which second operation condition fluid is transported in the first inlet conduit towards the low side at a second flow rate, wherein the first flow rate is lower than the second flow rate.

According to the invention, the pump assembly further comprises a recirculation conduit assembly adapted to provide a fluid transport from the high side to the low side during at least a part of the first operating condition.

By a pump assembly according to claim 1, water which is pumped through the pump may be recirculated in the recirculation conduit such that an increase water flow is obtained through the pump. This recirculation may provide for that the pump operates at an operating condition which is close to the optimum one for the pump even if the flow towards the pump per se is lower than the optimum flow for the pump.

Moreover, the recirculation may provide for that air, for instance in the form of air bubbles, possibly approaching the low side of the pump will be disintegrated into appropriately small bubbles before entering the low side. Moreover, the recirculated liquid may compress the air such that the volume of the air in the liquid is reduced before entering the pump.

As used herein, the expression “pump” relates to any type of device being adapted to move a fluid (i.e. liquid and/or gas) such that a higher pressure of the fluid is obtained. Moreover, the position of the pump wherein the fluid enters the pump is herein referred to as the “low side” whereas the position of the pump wherein the higher pressure fluid leaves the pump is herein referred to as the “high side”.

According to a preferred embodiment of the present invention, the recirculation conduit assembly comprises a separator, preferably a cyclone separator.

The provision of the separator results in that a liquid which is recirculated to the low side has a low, preferably close to zero, air content.

According to another embodiment of the present invention, the recirculation conduit assembly comprises an ejector which in turn comprises a motive fluid inlet, an entrained suction fluid inlet and an ejector outlet. The recirculation conduit assembly is adapted to provide a fluid communication between the high side and the motive fluid inlet during at least a part of the first operating condition.

The ejector will contribute to disintegrating and/or compressing the air even more which hence will provide for that more air may be pumped through the pump.

As used herein, the expression “ejector” relates to a device which uses the pressure energy of a motive fluid to draw in and possibly compress a suction fluid as well as outputting a mix of the motive and suction fluids.

According to a further embodiment of the present invention, the pump assembly is adapted to provide a fluid communication between the first inlet conduit assembly and the entrained suction fluid inlet during at least a part of the first operating condition.

According to another embodiment of the present invention, the pump assembly is adapted to provide a fluid communication between the ejector outlet and the low side during at least a part of the first operating condition.

According to a further embodiment of the present invention, the pump assembly further comprises a second inlet conduit assembly, wherein the pump assembly is adapted to provide a fluid communication between the second inlet conduit assembly and the low side during at least a part of the first operating condition.

The possibility of providing a second inlet conduit assembly is at least partially enabled due to the fact that the pump assembly of the present invention comprises a recirculation conduit. As such, even though the second inlet conduit assembly is adapted to be connected to an auxiliary system—such as a bilge water system of a marine structure for example—which generally provides lower liquid flows than the pump assembly, this difference in flows may be compensated by the recirculation conduit.

According to another embodiment of the present invention, the pump assembly is adapted to provide a fluid communication between the second inlet conduit assembly and the entrained suction fluid inlet.

According to another embodiment of the present invention, the pump assembly further comprises a coupling arrangement comprising an inner conduit and an outer conduit wherein both the inner conduit and the outer conduit are in fluid communication with the low side, the outer conduit substantially enclosing the inner conduit, the first inlet conduit assembly being in fluid communication with the outer conduit and the ejector outlet being in fluid communication with the inner conduit.

According to a further embodiment of the present invention, the inner conduit has an inner conduit inlet and an inner conduit outlet, wherein the outer conduit comprises a tapered portion at the location of the inner conduit outlet.

According to another embodiment of the present invention, the first inlet conduit assembly comprises an inlet separator, the inlet separator being adapted to be in fluid communication with the ballast tank as well as the low side.

The inlet separator provides the possibility of removing air from the first inlet conduit assembly, which removal may further reduce the effects of air mixed in the water of the pump assembly.

According to a further embodiment of the present invention, the pump assembly further comprises an outlet conduit assembly which is adapted to be in fluid communication with the inlet separator. The aforesaid outlet conduit may preferably be used for removing air from the inlet separator.

According to another embodiment of the present invention, the outlet conduit assembly further comprises a priming ejector comprising a priming ejector motive fluid inlet, a priming ejector entrained suction fluid inlet and a priming ejector outlet, the priming ejector entrained suction fluid inlet being adapted to be in fluid communication with the inlet separator.

With an arrangement according to the above, the liquid recirculated in the recirculation conduit assembly may be used for emptying the inlet separator of air. This is advantageous, since no additional drive means, such as an additional pump, is needed for the reduction of air in the pump assembly.

According to a further embodiment of the present invention, the priming ejector motive fluid inlet is adapted to be in fluid communication with the high side.

According to another embodiment of the present invention, the pump assembly further comprises a restoring conduit assembly comprising a restoring separator and a liquid seal, wherein the liquid seal is in fluid communication with the inlet separator and the restoring separator, the priming ejector outlet being in fluid communication with the restoring separator.

According to a further embodiment of the present invention, the pump assembly further comprises a cut-off conduit assembly providing a fluid communication between the liquid seal and the outlet conduit assembly.

According to another embodiment of the present invention, the restoring conduit further comprises an outlet conduit providing a fluid communication between the separator and the environment ambient of the pump assembly.

According to a further embodiment of the present invention, at least a portion of the first inlet conduit is located at a first elevation, the low side being located at an elevation below the first elevation.

A second aspect of the present invention relates to a marine structure comprising a pump assembly according the first aspect of the present invention.

A third aspect of the present invention relates to a method for transporting fluid from a first inlet conduit assembly of a pump assembly to a first outlet conduit assembly of the pump assembly, the pump assembly further comprising a pump which in turn comprises a low side and a high side, the method comprising the steps of: providing a fluid communication between the first inlet conduit assembly and the low side; providing a fluid communication between the high side and the first outlet conduit assembly, and providing that the pump is in an operating condition such that fluid is pumped from the low side to the high side.

According to the third aspect of the present invention, the method further comprises the steps of: determining a quality measure indicative of at least one property of the fluid pumped through the pump; comparing the quality measure with a predetermined interval, and if the quality measure falls within the predetermined interval, conveying at least a portion of the fluid at the high side back to the low side when the pump is in the operating condition.

As used herein, the expression “interval” encompasses both bounded (for instance [a, b] or (a, b)) as well as half bounded (such as (−∞, b] or [a, ∞)) intervals. As such, an example of an interval which falls within the above definition may be an interval which includes every value below a predetermined threshold value.

Moreover, an embodiment of the method according to the third aspect of the present invention may comprise the steps of comparing the quality measure with a plurality of predetermined intervals.

According to a predetermined embodiment of the third aspect of the present invention, the quality measure is indicative of the amount of gas—such as air—in the fluid and/or the flow rate of the fluid approaching the low side.

According to a preferred embodiment of the third aspect of the present invention, the first inlet conduit assembly comprises an inlet separator, wherein the step of determining the quality measure comprises a step of determining the amount of gas in the inlet separator.

A fourth aspect of the present invention relates to a computer program product comprising a computer program containing computer program code executable in a computer or a processor to implement steps of a method of the third aspect of the present invention. A fifth aspect of the present invention relates to an electronic control unit comprising such a computer program product.

With reference to the figures, FIG. 1 illustrates a schematic side view of a pump assembly 10 of the present invention. The pump assembly 10 in FIG. 1 is used in a ballast system of a marine structure (not shown), such as a ship or any other floating unit, which is a preferred application for the pump assembly 10 of the present invention although the pump assembly 10 of course also may be used in other fields of technology. Purely by way of example, the ballast system may preferably be used in a semi-submersible vessel, i.e. a vessel having a deck and a float and one or more supporting columns connecting the deck and the float to one another. A marine structure may be provided with a plurality of ballast systems—and hence a plurality of pump assemblies 10—and, in particular, a semi-submersible unit is generally provided with one ballast system comprising one or more pump assemblies 10 per supporting column (not shown).

As may be gleaned from FIG. 1, the ballast system, in which the pump assembly 10 of the present invention is installed, comprises a ballast tank 12. Generally, a ballast system comprises a plurality of ballast tanks as indicated by the dotted lines in FIG. 1. Moreover, the pump assembly 10 comprises a pump 14 comprising a low side 16 and a high side 18. The pump 14 may be any means for moving a liquid but preferably a rotodynamic pump, such as a centrifugal pump, is used in the pump assembly 10.

The pump assembly 10 also comprises a first inlet conduit assembly 20 which in the FIG. 1 implementation of the ballast system is adapted to provide a fluid communication between the ballast tank 12 and the low side 16 of the pump 14. In FIG. 1, the first inlet conduit assembly 20 includes a plurality of pipes 22, 24, 26 which are connected to one another so as to form the first inlet conduit assembly 20 although one continuous pipe may be used as a first inlet conduit assembly. Moreover, the first inlet conduit assembly 20 preferably comprises a valve 28 for controlling the liquid flow in and/or out of the ballast tank 12.

Furthermore, the ballast system generally comprises a liquid supply assembly 30 and a liquid discharge assembly 32 —which liquid discharge assembly 32 may also be referred to as a first outlet conduit assembly 32 of the pump assembly 10 of the present invention—wherein the liquid supply assembly 30 may be connected to the first inlet conduit assembly 20, preferably through a valve 34, whereas the liquid discharge assembly 32 generally is in fluid communication with the high side 18 of the pump 14. Generally, the liquid used in the ballast system is sea water but in some specific applications of the ballast systems, other liquids may be used.

FIG. 1 illustrates the pump assembly 10 in a first operating condition wherein the ballast tank 12 of the ballast system is emptied of liquid. As such, the direction of flow is indicated by arrows and as may be realized from FIG. 1, the liquid is conducted from the ballast tank 12, through the first inlet conduit assembly 20, the pump 14 and the first outlet conduit assembly 32 (or discharge assembly). As such, in the first operating condition the liquid is pumped from the low side 16 to the high side 18 of the pump 14. If the liquid used in the pump assembly 10 is sea water, the liquid is generally conducted from the discharge assembly 32 to the water ambient of the pump assembly 10, i.e. the water ambient of the marine structure (not shown) in which the pump assembly 10 is located.

Preferably, the liquid discharge assembly 32 is adapted to discharge liquid at a level above the tank 12. More preferred, the liquid discharge assembly 32 is adapted to discharge liquid at a level above the operating water line of the marine structure (not shown) such that the risk of having sea water entering the liquid discharge assembly 32 from above is low. Purely by way of example, if the marine structure is a semi-submersible unit (not shown), the liquid discharge assembly 32 may be adapted to discharge liquid at a level which is approximately 10-15 meters above the still water line when the submersible unit is in an operational draught.

FIG. 1 illustrates that the pump assembly 10 of the present invention also comprises a recirculation conduit assembly 36 adapted to provide a fluid communication between the high side 18 and the low side 16 of the pump 14 during at least a part of the first operating condition. The recirculation conduit assembly 36 may in its simplest form be a pipe connected to the high side 18 and the low side 16. However, and as is illustrated in FIG. 1, the recirculation conduit assembly 36 preferably comprises a separator 38, preferably a cyclone separator—in fluid communication with the high side 18—in addition to a pipe 40 providing a fluid communication between the separator and the low side 16. The advantage of the presence of the aforementioned separator 38 is that liquid recirculated through the recirculation conduit assembly 36 has a low amount of air.

Although the recirculation conduit assembly 36 in FIG. 1 is illustrated as a separate pipe, the recirculation conduit assembly 36 may be obtained in a plurality of ways. Purely by way of example, if the pump 14 comprises a housing (not shown in FIG. 1) the recirculation conduit assembly 36 may be obtained by arranging one or more channels in the housing providing a fluid communication between the high side 18 and the low side 16.

Moreover, the pump assembly 10 of the present invention preferably comprises determining means 39 for determining the flow rate and/or for determining the amount of air mixed in the liquid entering the low side 16 of the pump 14. Additionally, the recirculation conduit assembly 36 may be provided with control arrangements 41 such as one or more valves, for controlling the flow rate through the recirculation conduit assembly 36. The positions of the determining means 39 and the control arrangements 41 in FIG. 1 in relation to the pump assembly 10 is only exemplifying and in other embodiments of the pump assembly 10 of the present invention, the aforesaid positions may be different.

As such, if it is realized—during the first operating condition illustrated in FIG. 1 —that the flow rate of the liquid entering the low side 16 is within a predetermined interval, e.g. below a predetermined desired value, liquid may be recirculated through the recirculation conduit assembly 36 in order to increase the flow rate to thereby obtain a more preferred flow for the pump 14. Optionally, or in addition, if it is realized that the amount of air in the liquid entering the low side 16 is above a predetermined threshold value, recirculation may also be employed in order to disintegrate the air into small bubbles and/or to compress the air. To this end, the recirculation conduit assembly 36 preferably comprises nozzles (not shown) in the vicinity of the low side 16 which nozzles are adapted to disintegrate the air into the liquid.

Moreover, a ballast system preferably comprises two pump assemblies 10 in order to enhance the reliability of the ballast system.

FIG. 2 illustrates another embodiment of the pump assembly 10 of the present invention. As may be realized from FIG. 2, instead of the aforementioned nozzles, the recirculation conduit assembly 36 comprises an ejector 42 which in turn comprises a motive fluid inlet 44, an entrained suction fluid inlet 46 and an ejector outlet 48.

As indicated by arrows in FIG. 2, in the operational condition illustrated therein, the recirculation conduit assembly 36 provides a fluid communication between the high side 18 and the motive fluid inlet 44 such that the ejector 42 will be fed by liquid recirculated from the high side 18. As such, if the flow rate in the first inlet conduit assembly 20 is below a desired value, the ejector 42 will provide an increased flow rate prior to the low side. Moreover, the ejector 42 may also compress possible air bubbles in the first inlet conduit assembly 20. To this end, the volume—rather than the mass—of the air occluded in the liquid is a critical parameter as regards the function of the pump 14.

FIG. 3A illustrates a further embodiment of the pump assembly 10 of the present invention wherein the pump assembly 10 further comprises a second inlet conduit assembly 50 and the pump assembly 10 is adapted to provide a fluid communication between the second inlet conduit assembly 50 and the low side 16 during at least a part of the first operating condition.

The second inlet conduit assembly 50 may in turn be connected to any one of a plurality of auxiliary liquid distribution systems (not shown) of the marine structure (not shown) including, but not limited to: a fire water system or a cooling system. However, in a preferred implementation of the FIG. 3A embodiment, the second inlet conduit assembly 50 is connected to a bilge system (not shown) of the marine structure.

Traditionally, the bilge system of a marine structure is connected to an individual bilge pump dedicated to serve the bilge system, which bilge pump generally has a lower capacity than the pump 14 of the pump assembly 10. However, with a pump assembly 10 as presented in FIG. 3A, the pump 14 of the pump assembly 10 may in fact also be used for pumping bilge water from the bilge system and this possibility is at least partially enabled due to the presence of the recirculation conduit assembly 36. As may be gleaned from FIG. 3A, in the embodiment of the pump assembly 10 disclosed therein, a fluid communication is provided between the second inlet conduit assembly 50 and the low side 16 during at least a part of a second operating condition at which water is pumped from the bilge system (not shown). The second operating condition is indicated by arrows in FIG. 3A.

Moreover, FIG. 3A teaches that the second inlet conduit assembly 50 —in the second operating condition—is in fluid communication with the entrained suction fluid inlet 46 of the ejector 42. As such, liquid pumped from the second inlet conduit assembly 50 will pass the ejector 42 on its way towards the low side 16. The advantages of this passing is inter alia that any air bubbles in the second inlet conduit assembly 50 will be disintegrated and/or compressed when passing through the ejector 42 as wall as that the liquid entering the low side 16 will have an appropriately high flow as regards the capacity of the pump 14.

FIG. 3B illustrates the FIG. 3A embodiment when the pump assembly 10 is in a first operating condition, i.e. when liquid is pumped from the ballast tank 12. As may be realized from FIG. 3 b, the pump assembly 10 comprises a bypass conduit 58 which is adapted to provide a fluid communication between the first inlet conduit assembly 20 and the entrained suction fluid inlet 46 of the ejector 42. As such, when the FIG. 3B pump assembly 10 is in the first operating condition, a bypass valve 54 may—depending on the flow rate in the first inlet conduit assembly 20—be at least partially opened thus providing a fluid communication between the first inlet conduit assembly 20 and the entrained suction fluid inlet 46. At the same time a first inlet valve 52 may be closed or at least partially open. If the first inlet valve 52 is at least partially open, a fluid communication is provided between the first inlet conduit assembly 20 and a coupling arrangement 60 (not shown in FIG. 3B).

FIG. 3C illustrates a cross section of the coupling arrangement 60 which arrangement comprises an inner conduit 62 and an outer conduit 64 wherein both the inner conduit 62 and the outer conduit 64 are in fluid communication with the low side 16 of the pump 14. Moreover, FIG. 3C illustrates that the outer conduit 64 substantially encloses the inner conduit 62, and that the ejector outlet 48 is in fluid communication with the inner conduit 62. As may be gleaned from FIG. 3C, the inner conduit has an inner conduit inlet 66 and an inner conduit outlet 68, wherein the outer conduit 64 comprises a tapered portion 70 at the location of the inner conduit outlet 68. The tapered portion 70 of the outer conduit 64 will ensure that liquid transported through the inner conduit 62 and/or the outer conduit 64 will assume a preferred direction of flow—i.e. a substantially parallel to a direction from the inner conduit inlet 66 to the inner conduit outlet 68—prior to entering the low side 16.

FIG. 3C also teaches that the recirculation conduit assembly 36 may comprise a recirculation bypass conduit 72 adapted to provide a fluid communication between the high side and the outer conduit 64 without passing the ejector 42.

The coupling arrangement 60 as well as the pump 14 and at least a portion of the recirculation conduit assembly 36 of the FIG. 3A to 3C pump assembly 10 preferably is located below the first and second inlet conduit assemblies 20, 50. In other words, at least a portion of the first inlet conduit 20 is located at a first elevation, at least a portion of the second inlet conduit 50 is located at a second elevation and the low side 16 is located at a third elevation which third elevation is below the first and second elevations. This preferred location of the coupling arrangement 60, the pump 14 and possibly also the recirculation conduit assembly 36 provides for that at least the coupling arrangement 60 is filled with liquid when the pump 14 is actuated. As such, the risk of starting the pump 14 in a condition wherein the coupling arrangement 60 is at least partially filled with air is at least substantially reduced.

Moreover, the pump assembly 10 of the present invention could be adapted to provide a liquid distribution at a low flow rate from a liquid source—such as the liquid supply assembly 30—to the pump 14. Such a liquid distribution may for instance be used prior to starting the pump 14 in order to ensure that at least the portion of the ballast system 10 which is located in the vicinity of the low side 16 is filled with water prior to starting the pump 14 (i.e. in order to perform an initial priming of the pump 14). Instead of, or in combination with, the aforesaid initial priming, the liquid distribution from the supply assembly 30 to the pump 14 may be performed for cooling purposes, i.e. to provide additional liquid to the pump 14 in order to ensure that the liquid circulated in the recirculation conduit assembly 36 has a temperature which is below a predetermined value. To this end, the previously discussed determining means (not shown in FIG. 3C) may comprise means for determining the temperature in the recirculation conduit assembly 36 and/or the liquid entering the low side 16.

In some implementations of the FIG. 3B embodiment, the second inlet conduit assembly 50 may be omitted such that substantially only a portion of the liquid conducted through the first inlet conduit assembly 20 is adapted to enter the entrained suction fluid inlet 46.

FIG. 4 illustrates a side view of an additional embodiment of the pump assembly 10 of the present invention. As may be gleaned from FIG. 4, first inlet conduit assembly 20 of the pump assembly 10 illustrated therein comprises an inlet separator 74. As for the previous embodiments, the first inlet conduit assembly 20 is adapted to be in fluid communication with at least one ballast tank (not shown) of the pump assembly 10. Moreover, the inlet separator 74 is in fluid communication with the low side 16 of the pump 14. Furthermore, a second inlet conduit assembly 50 is in fluid communication with the inlet separator 74. In the embodiment of the pump assembly 10 illustrated in FIG. 4, the second inlet conduit assembly 50 is connected to a bilge system (not shown) of the marine structure (not shown). However, in other embodiments of the pump assembly 10 of the present invention, the second inlet conduit assembly 50 may be omitted such that only one inlet conduit assembly, namely the first inlet conduit assembly 20, is in fluid communication with the inlet separator 74.

In addition, FIG. 4 illustrates that the pump assembly 10 disclosed therein may comprise a recirculation conduit assembly 36 adapted to provide a fluid communication between the high side 18 and the low side 16 of the pump 14. Purely by way of example, the implementation of the FIG. 4 recirculation conduit assembly 36 may be identical to any one of the implementations of the recirculation conduit assemblies 36 as discussed in conjunction with the embodiments of the pump assembly 10 discussed hereinabove with reference to any of FIG. 1 to FIG. 3. Moreover, and as is illustrated in the FIG. 4 embodiment of the pump assembly 10, the recirculation conduit assembly 36 may be provided without a separator 38 since the inlet separator 74 of the FIG. 4 pump assembly 10 generally will provide that the fluid (generally a liquid) travelling from the inlet separator 74 to the pump 14 has a low air content. However, in specific embodiments of the FIG. 4 pump assembly 10, the recirculation conduit assembly 36 may also be omitted, since the FIG. 4 pump assembly 10 in fact already comprises a recirculation conduit assembly 76, as will be discussed more thoroughly hereinbelow.

As may be gleaned from FIG. 4, the pump assembly 10 comprises an outlet conduit assembly 78 which is adapted to be in fluid communication with the inlet separator 74. In fact, the outlet conduit assembly may even be adapted to always be in fluid communication with the inlet separator 74. The outlet conduit assembly 78 is preferably connected to the uppermost portion of the inlet separator 74 such that gasses, mostly air, may be extracted from the inlet separator 74.

In order to enhance the extraction of air from the inlet separator 74, the pump assembly 10 preferably comprises a motive fluid conduit assembly 80 providing a fluid communication between the high side 18 of the pump 14 and a motive fluid inlet 82 of a priming ejector 84, which priming ejector further comprises a priming ejector entrained suction fluid inlet 86 and a priming ejector outlet 88 wherein the priming ejector entrained suction fluid inlet 86 is connected to the outlet conduit assembly 78 such that a fluid communication is provided between the inlet separator 74 and the entrained suction fluid inlet 86. As such, at least a portion of liquid from the high side 18 of the pump 14 is—at least during certain predetermined operating conditions—transported to the motive fluid inlet 82 such that the liquid will contribute to drawing out the air in the inlet separator 74 through the outlet conduit assembly 78.

An example of a predetermined operating condition wherein liquid is allowed to flow from the high side 18 to the motive fluid inlet 82 may be when an air volume above a predetermined threshold volume is identified in the inlet separator 74. To this end, the pump assembly 10 of the present invention may preferably comprise a sensor arrangement 90 adapted to determine the volume of the air enclosed in the inlet separator 74. Such a sensor arrangement 90 may preferably be in communication with a control assembly 92 —indicated by a single valve 92 in FIG. 4 —controlling the amount of liquid flow through the motive fluid conduit assembly 80.

When liquid flows in the motive fluid conduit assembly 80 so as to feed the priming ejector 84, a mixture of air and liquid will leave the priming ejector 84 through the priming ejector outlet 88 which in turn is in fluid communication with a restoring conduit assembly 94 which in the FIG. 4 embodiment comprises a restoring separator 96 and a liquid seal 98. As may be realized from FIG. 4, the priming ejector outlet 88 may preferably discharge into the restoring separator 96. The restoring separator 96 further comprises an air discharge conduit 100 such that air in the restoring separator 96 may leave the pump assembly 10 of the present invention.

The liquid seal 98 preferably comprises a conduit—or a plurality of conduits joined together so as to form a continuous conduit arrangement—which in turn comprises a lower bend 102 and an upper bend 104 wherein the first and second bend are distanced from one another by a vertical distance V, which vertical distance preferably is more than 10 meters, more preferably more than 11 meters.

As may be realized when studying the FIG. 4 embodiment, the motive fluid conduit assembly 80, the restoring conduit assembly 94, the inlet separator 74 and portions of the first inlet conduit assembly 20 together form a motive fluid recirculation conduit assembly 76 for the ballast water system 10, which motive fluid recirculation conduit assembly 76 provides a fluid communication between the high side 18 and the low side 16 to thereby enable liquid transport from the high side 18 to the low side 16. The motive fluid recirculation conduit assembly 76 just described may in some embodiments of the present invention be the only recirculation conduit assembly of the pump assembly 10 adapted to provide a fluid passage from the high side 18 to the low side 16. However, and as been previously discussed, other embodiments of the pump assembly 10 of the present invention may also comprise an additional recirculation conduit assembly 36 such as any one of the recirculation conduit assemblies 36 presented in the FIG. 1 to FIG. 3 embodiments.

The FIG. 4 pump assembly 10 also comprises a cut-off conduit assembly 106 providing a fluid communication between the liquid seal 98 —preferably at the location of the upper bend 104- and the outlet conduit assembly 78 in order to reduce the risk of having the liquid seal 98 emptied of liquid due to inter alia a siphon action.

As may be gleaned from FIG. 4, the pump assembly 10 illustrated therein also comprises a recirculation conduit control arrangement 41—such as one or more valves—adapted to control the flow rate through the recirculation conduit assembly 36. Moreover, the FIG. 4 pump assembly 10 comprises a discharge control arrangement 108 adapted to control the flow rate through the discharge assembly 32.

The motive fluid control arrangement 92, the recirculation conduit control arrangement 41 and the discharge control arrangement 108 may preferably be operated individually and/or in combination in order to ensure that the amount of gas, such as air in the inlet separator 74 —and consequently in the fluid approaching the pump 14—is kept appropriately low. To this end, a control method is preferably used the steps of which are briefly discussed herein below with reference to the FIG. 4 pump assembly 10 as well as the flow chart illustrated in FIG. 5.

In the aforesaid control method, the amount of air in the inlet separator 74 is determined, preferably by using the sensor arrangement 90 or any other suitable means for determining the air content in the inlet separator 74. The thus determined amount of air A_(c) in the inlet separator 74 is then compared to a plurality of predetermined threshold values T₁, T₂, T₃ and T₄.

If the amount of air A_(c) in the inlet separator 74 is below a first threshold value T₁, the motive fluid control arrangement 92 and the recirculation conduit control arrangement 41 are closed whereas the discharge control arrangement 108 is in a position so as to allow a maximum flow through the discharge assembly 32. Thus, the pump assembly 10 is then a condition wherein fluid transport through the motive fluid recirculation conduit assembly 76 as well as the recirculation conduit assembly 36 is prevented in order to ensure that a high flow rate is obtained from the first inlet conduit assembly 20 to the discharge assembly 32.

However, if the amount of air A_(c) in the inlet separator 74 is equal to or above the first threshold value T₁, the motive fluid control arrangement 92 is operated to an at least partially opened condition such that fluid transport through the motive fluid recirculation conduit assembly 76 is enabled. This is indicated in boxes 112 and 114 in FIG. 5. As such, the motive fluid inlet 82 of the priming ejector 84 is fed with fluid—often liquid such as water—resulting in that the priming ejector 84 will extract air from the inlet separator 74. Moreover, when opening the motive fluid control arrangement 92, the flow rate from the first inlet conduit assembly 20 to the inlet separator 74 is reduced. This reduction of the flow rate is preferred, since an air amount A_(c) above the first threshold value T₁ is indicative of that the air content of the fluid in the first inlet conduit assembly 20 is high. Thus, a reduction of the flow rate from the first inlet conduit assembly 20 to the inlet separator 74 is desired in order to be able to extract the air from the inlet separator 74 in an appropriate manner. Moreover, the reduction of the flow rate in the first inlet conduit assembly 20 —when using the above step may be obtained without obtaining a corresponding reduction of the flow rate towards the low side 16 of the pump 14. Instead, due to the recirculation of fluid through the motive fluid recirculation conduit assembly 76, a constant flow rate—preferably a flow rate close to the optimum operating condition of the pump 14 —may be maintained.

Moreover, if the amount of air A_(c) in the inlet separator 74 is equal to or above a second threshold value T₂—which second threshold value T₂ is greater than the first threshold value T₁—the recirculation conduit control arrangement 41 is operated to an at least partially opened condition such that fluid transport through the recirculation conduit assembly 36 is enabled. This is indicated in boxes 116 and 118 in FIG. 5. As such, a recirculation of fluid is obtained from the high side 18 to the low side 16 resulting in a further reduction of the flow rate from the first inlet conduit assembly 20 to the inlet separator 74. As for the step above corresponding to boxes 112 and 114, the opening of the recirculation conduit control arrangement 41 may provide for that the reduction of the flow rate from the first inlet conduit assembly to the inlet separator 74 is reduced without obtaining a reduction of the flow rate to the low side 16. In certain embodiments of the control method, the steps corresponding to boxes 116 and 118 may be omitted.

Additionally, if the amount of air A_(c) in the inlet separator 74 is equal to or above a third threshold value T₃—which third threshold value T₃ is greater than the second threshold value T₂—the discharge control arrangement 108 is operated to throttle the discharge assembly 32 such that a reduced flow rate is obtained in the discharge assembly 32. This is indicated in boxes 120 and 122 in FIG. 5. This reduction of flow rate in the discharge assembly 32 further reduces the flow rate from the first inlet conduit assembly 20 to the inlet separator 74. The reduction of the flow rate in the discharge assembly 32 will generally result in a corresponding reduction of the flow rate towards the low side 16. However, due to the recirculation in the motive fluid recirculation conduit assembly 76 and the recirculation conduit assembly 36, the flow rate towards the low side 16 may nevertheless be maintained within a preferred flow rate interval for the pump 14. The discharge control arrangement 108 is preferably adapted to perform a continuous—i.e. stepless—throttling of the discharge assembly 32. As such, the steps of the control method indicated in boxes 120 and 122 in FIG. 5 may comprise a step of determining how much the amount of air A_(c) in the inlet separator 74 exceeds—i.e. not just that it actually is equal to or above—the third threshold value T₃. Depending on the information as regards how much the amount of air A_(c) exceeds the third threshold value T₃, the discharge control arrangement 108 is operated to a throttle percentage corresponding to a function of the difference A_(c) T₃. In certain embodiments of the control method, the steps corresponding to boxes 120 and 122 may be omitted, for instance if it not desired to throttle the discharge assembly 32.

Finally, if the amount of air A_(c) in the inlet separator 74 is equal to or above a fourth threshold value T₄—which fourth threshold value T₄ is greater than the third threshold value T₃—the discharge control arrangement 108 is operated to a closed condition such that a flow to the discharge assembly 32 is prevented. This is indicated in boxes 124 and 126 in FIG. 5. This prevention of flow to discharge assembly 32 even further reduces the flow rate from the first inlet conduit assembly 20 to the inlet separator 74. Since the flow rate in the discharge assembly 32 in this case is substantially zero, the flow rate towards the low side 16 in the present condition generally corresponds to the sum of the flow rates through the motive fluid recirculation conduit assembly 76 and the recirculation conduit assembly 36. However, the conduit assemblies are preferably designed so as to allow flow rates of appropriate magnitudes such that the flow rate towards the low side 16 may nevertheless be maintained within a preferred flow rate interval for the pump 14. Purely by way of example, the motive fluid recirculation conduit assembly 76 and the recirculation conduit assembly 36 may be designed so that they together provide a flow rate which is within the range of 50%-70%, preferably 60%-65%, of the preferred flow rate of the pump 14. In certain embodiments of the control method, the steps corresponding to boxes 124 and 126 may be omitted, for instance if it is not desired to close the discharge assembly 32.

The steps of the control method discussed hereinabove with reference to FIG. 4 and FIG. 5 may preferably be repeated, either continuously, periodically at a predetermined frequency (e.g. every 30 seconds) or by the actuation of an operator.

Further, in certain implementations of the control method, the steps may be performed in a reversed order as compared to the FIG. 5 flow chart. Moreover, implementations of the above described control method may comprise additional control steps. Purely by way of example, if it is determined that the amount of air A_(c) in the inlet separator 74 is equal to or above a third threshold value T3 and the discharge assembly 32 is throttled (c.f. boxes 120 and 122 in FIG. 5) certain implementations of the control method may comprise the steps of continuously or at a predetermined frequency determining the amount of air A_(c) in the inlet separator 74 and—if needed—re-adjusting the throttling of the discharge assembly 32. Additionally, the control method may preferably comprise a step of closing the motive fluid control arrangement 92 as well as the recirculation conduit control arrangement 41 and operating the discharge control arrangement 108 so as to allow a maximum flow through the discharge assembly 32 prior to executing the steps in FIG. 5.

As such, the just described control method may provide for that the air content of the fluid entering the low side 16 of the pump 14 is kept below a predetermined desired value and at the same time provide for that the flow rate towards the low side 16 is kept close to a desired flow rate or at least within a desired flow rate interval.

Moreover, any one of the steps of the control method presented hereinabove may be performed manually. However, more preferred, all of the above steps are performed by a control unit 109 which preferably comprises an electronic control unit (ECU) with a computer program product adapted to implement the above steps of the control method. As such, the control unit 109 is preferably adapted to communicate with at least the arrangement 90, the motive fluid control arrangement 92, recirculation conduit control arrangement 41 and the discharge control arrangement 108. Also, a control method which does not involve the steps corresponding to boxes 116 and 118 may be used in a fluid 10 which does not comprise a recirculation conduit assembly 36.

Certain embodiments and features have been described using a set of numerical upper limits and a set of numerical lower limits. Ranges from any lower limit to any upper limit are contemplated unless otherwise indicated. Certain lower limits, upper limits and ranges appear in one or more claims below. All numerical values are “about” or “approximately” the indicated value, and take into account numerical error and variations that would be expected by a person having ordinary skill in the art.

Various terms have been defined above. To the extent a term used in a claim is not defined above, it should be given the broadest definition persons in the pertinent art have given that term as reflected in at least one printed publication or issued patent. Furthermore, all patents, test procedures, and other documents cited in this application are fully incorporated by reference to the extent such disclosure is not inconsistent with this application and for all jurisdictions in which such incorporation is permitted.

While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow. 

1) A pump assembly comprising a pump which in turn comprises a low side and a high side, said pump assembly comprising a first inlet conduit in fluid communication with said low side, said pump assembly being adapted to provide a first operation condition in which first operation condition fluid is transported in said first inlet conduit towards said low side at a first flow rate, said pump assembly further being adapted to provide a second operation condition in which second operation condition fluid is transported in said first inlet conduit towards said low side at a second flow rate, wherein said first flow rate is lower than said second flow rate characterized in that said pump assembly further comprises a recirculation conduit assembly adapted to provide a fluid transport from said high side to said low side during at least said first operation condition. 2) The pump assembly according to claim 1, wherein said recirculation conduit assembly comprises a separator, preferably a cyclone separator. 3) The pump assembly according to claim 1, wherein said recirculation conduit assembly comprises an ejector which in turn comprises a motive fluid inlet, an entrained suction fluid inlet and an ejector outlet, wherein said recirculation conduit assembly is adapted to provide a fluid communication between said high side and said motive fluid inlet during at least a part of said first operating condition. 4) The pump assembly according to claim 3, wherein said pump assembly is adapted to provide a fluid communication between said first inlet conduit assembly and said entrained suction fluid inlet during at least a part of said first operating condition. 5) The pump assembly according to claim 3, wherein said pump assembly is adapted to provide a fluid communication between said ejector outlet and said low side during at least a part of said first operating condition. 6) The pump assembly according to claim 3, wherein said pump assembly further comprises a coupling arrangement comprising an inner conduit and an outer conduit wherein both said inner conduit and said outer conduit are in fluid communication with said low side, said outer conduit substantially enclosing said inner conduit, said first inlet conduit assembly being in fluid communication with said outer conduit and said ejector outlet being in fluid communication with said inner conduit. 7) The pump assembly according to claim 6, wherein said inner conduit has an inner conduit inlet and an inner conduit outlet, wherein said outer conduit comprises a tapered portion at the location of said inner conduit outlet. 8) The pump assembly according to claim 1, wherein said pump assembly further comprises a second inlet conduit assembly, wherein said pump assembly is adapted to provide a fluid communication between said second inlet conduit assembly and said low side during at least a part of said first operating condition. 9) The pump assembly according to claim 8, wherein said pump assembly is adapted to provide a fluid communication between said second inlet conduit assembly and said entrained suction fluid inlet. 10) The pump assembly according to claim 1, wherein said first inlet conduit assembly comprises an inlet separator, said inlet separator being adapted to be in fluid communication with said ballast tank as well as said low side. 11) The pump assembly according to claim 10, wherein said pump assembly further comprises an outlet conduit assembly which is adapted to be in fluid communication with said inlet separator. 12) The pump assembly according to claim 11, wherein said outlet conduit assembly further comprises a priming ejector comprising a priming ejector motive fluid inlet, a priming ejector entrained suction fluid inlet and a priming ejector outlet, said priming ejector entrained suction fluid inlet being adapted to be in fluid communication with said inlet separator. 13) The pump assembly according to claim 12, wherein said priming motive fluid inlet is adapted to be in fluid communication with said high side. 14) The pump assembly according to claim 12, wherein said pump assembly further comprises a restoring conduit assembly comprising a restoring separator and a liquid seal, wherein said liquid seal is in fluid communication with said inlet separator and said restoring separator, said priming ejector outlet being in fluid communication with said restoring separator. 15) The pump assembly according to claim 14, wherein said pump assembly further comprises a cut-off conduit assembly providing a fluid communication between said liquid seal and said outlet conduit assembly. 16) The pump assembly according to claim 14, wherein said restoring conduit further comprises an outlet conduit providing a fluid communication between said separator and the environment ambient of said pump assembly. 17) The pump assembly according to claim 1, wherein at least a portion of said first inlet conduit is located at a first elevation, said low side being located at an elevation below said first elevation. 18) A method for transporting fluid from first inlet conduit assembly of a pump assembly to a first outlet conduit assembly of said pump assembly, said pump assembly further comprising a pump which in turn comprises a low side and a high side, said method comprising the steps of: providing a fluid communication between said first inlet conduit assembly and said low side; providing a fluid communication between said high side and said first outlet conduit assembly; and providing that said pump is in an operating condition such that fluid is pumped from said low side to said high side. 19) The method of claim 18, further comprising the steps of: determining a quality measure indicative of at least one property of said fluid pumped through said pump; comparing said quality measure with a predetermined interval, and if said quality measure falls within said predetermined interval, conveying at least a portion of said fluid at said high side back to said low side when said pump is in said operating condition. 20) The method according to claim 19, wherein said step of determining said quality measure comprises a step of determining the amount of gas (AC) in an inlet separator. 